Legal claims defining the scope of protection. Each claim is shown in both the original legal language and a plain English translation.
1. A terminal, comprising: a first card slot; a second card slot; a first antenna; a second antenna; a third antenna; a fourth antenna; a first baseband processor coupled to the first card slot; a second baseband processor coupled to the second card slot; a first radio frequency chip coupled to the first baseband processor, wherein the first baseband processor is further coupled to the first antenna using the first radio frequency chip, wherein the first radio frequency chip is further coupled to the first antenna to form a first channel, wherein the first baseband processor is further coupled to the second antenna using the first radio frequency chip, and wherein the first radio frequency chip is coupled to the second antenna to form a second channel; a second radio frequency chip coupled to the second baseband processor, wherein the second baseband processor is coupled to the third antenna using the second radio frequency chip, wherein the second radio frequency chip is further coupled to the third antenna to form a third channel, wherein the second baseband processor is further coupled to the fourth antenna using the second radio frequency chip, and wherein the second radio frequency chip is further coupled to the fourth antenna to form a fourth channel; and one or more first switches coupled to the first baseband processor and the first radio frequency chip between the first baseband processor and the first radio frequency chip, wherein the first baseband processor, the second baseband processor, the first radio frequency chip, and the second radio frequency chip all are configured to support an access capability of a third-generation mobile communications technology (3G) or later-generation mobile communications technology such that the first baseband processor and the second baseband processor are configured to simultaneously perform services of the 3G or later-generation mobile communications technology, wherein the first channel, the second channel, the third channel, and the fourth channel are configured to transmit data between the terminal and an external device; and further comprising one or more second switches, wherein the first baseband processor is coupled to the second radio frequency chip using the one or more second switches, and wherein the first baseband processor is configured to transmit the data using the first channel and the third channel when the first baseband processor is coupled to the second radio frequency chip and the third channel is idle.
This invention relates to a dual-card terminal with enhanced connectivity for 3G or later-generation mobile communications. The terminal addresses the need for simultaneous multi-card operation with improved data transmission capabilities. The device includes two card slots, each connected to a dedicated baseband processor. Each baseband processor interfaces with a radio frequency (RF) chip, which manages multiple antennas to establish independent data channels. The first baseband processor connects to a first RF chip, which links to two antennas forming separate channels. Similarly, the second baseband processor connects to a second RF chip, which links to two additional antennas forming two more channels. Switches between the baseband processors and RF chips enable flexible routing. The system supports simultaneous 3G or later-generation services across both cards, allowing independent or combined data transmission. When a channel is idle, the first baseband processor can route data through the second RF chip's channels, optimizing bandwidth usage. This design enhances multi-card terminal performance by enabling dynamic channel allocation and efficient data handling.
2. The terminal of claim 1 , further comprising one or more second switches, wherein the first baseband processor is coupled to the second radio frequency chip using the one or more second switches, wherein the first baseband processor is configured to transmit the data using the first channel, the second channel, the third channel, and the fourth channel when the first baseband processor is coupled to the second radio frequency chip and third channel and the fourth channel are idle.
A wireless communication terminal includes a first baseband processor and a second radio frequency (RF) chip, where the first baseband processor is coupled to the second RF chip via one or more second switches. The terminal also includes a first RF chip, where the first baseband processor is coupled to the first RF chip via one or more first switches. The first baseband processor is configured to transmit data using multiple channels, including a first channel, a second channel, a third channel, and a fourth channel. When the first baseband processor is coupled to the second RF chip and the third and fourth channels are idle, the first baseband processor can transmit data using all four channels. This configuration allows for flexible channel allocation and improved data transmission efficiency by utilizing idle channels when available. The switches enable dynamic coupling between the baseband processor and the RF chips, optimizing resource usage and enhancing communication performance. The system is designed to handle high-bandwidth data transmission by leveraging multiple channels, particularly when certain channels are underutilized.
3. The terminal of claim 1 , wherein the first baseband processor and the second baseband processor are integrated in one processor, wherein the first baseband processor is coupled to a first subscriber identity module (SIM) card in the first card slot and the second baseband processor is coupled to a second SIM card in the second card slot, and wherein the first baseband processor and the second baseband processor are configured to simultaneously perform fourth-generation (4G) or later-generation communication services using the first SIM card and the second SIM card, respectively.
A dual-SIM terminal integrates a single processor that functions as both a first and second baseband processor, enabling simultaneous 4G or later-generation communication services using two separate SIM cards. The terminal includes two card slots, each housing a distinct SIM card. The first baseband processor is coupled to the first SIM card in the first slot, while the second baseband processor is coupled to the second SIM card in the second slot. Both processors operate concurrently, allowing the terminal to maintain independent communication sessions on each SIM card without interference. This design eliminates the need for separate processors, reducing hardware complexity while supporting high-speed data services on both SIMs. The solution addresses the challenge of managing multiple SIMs in a single device, particularly for users requiring dual connectivity for work and personal use or roaming across different networks. The integrated processor ensures efficient resource allocation and seamless switching between networks, enhancing performance and user experience.
4. The terminal of claim 1 , wherein the second antenna and the fourth antenna share a same antenna.
**Technical Summary for Prior Art Search Database** This invention relates to wireless communication terminals, specifically addressing the challenge of optimizing antenna configurations to improve signal reception and transmission efficiency. The terminal includes multiple antennas to support various communication functions, such as cellular, Wi-Fi, and GPS. A key aspect is the integration of multiple antennas into a single physical structure to reduce size and complexity while maintaining performance. The terminal features at least four antennas, where the second and fourth antennas are combined into a single shared antenna. This shared antenna is designed to handle multiple communication bands or protocols, reducing the need for separate antennas while minimizing interference and signal degradation. The shared antenna may be a multi-band or multi-mode antenna, capable of dynamically switching between different frequency ranges or communication standards as needed. The terminal also includes a first antenna and a third antenna, each dedicated to specific functions, such as primary cellular communication or GPS reception. The shared antenna configuration allows the terminal to maintain full functionality while reducing hardware complexity and cost. This approach is particularly useful in compact devices where space is limited, such as smartphones or wearable electronics. The invention aims to improve signal quality, reduce interference, and optimize space utilization in wireless communication terminals by strategically combining multiple antennas into a single component.
5. The terminal of claim 1 , wherein the first antenna and the third antenna are main antennas, and wherein the second antenna and the fourth antenna are diversity antennas.
Antenna systems for wireless communication devices often require multiple antennas to support various functions such as main transmission/reception and diversity reception to improve signal quality and reliability. A wireless communication terminal includes a first antenna, a second antenna, a third antenna, and a fourth antenna. The first and third antennas are designated as main antennas, primarily responsible for transmitting and receiving primary signals. The second and fourth antennas are designated as diversity antennas, which assist in improving signal reception by providing alternative signal paths to mitigate multipath fading and interference. The terminal may also include a switching mechanism to dynamically allocate antenna functions based on signal conditions or operational requirements. This configuration enhances overall communication performance by optimizing signal transmission and reception through specialized antenna roles. The system may further integrate with other components, such as radio frequency modules or signal processing units, to manage antenna selection and signal routing efficiently. The design aims to improve signal stability and coverage in wireless communication environments.
6. The terminal of claim 1 , wherein the first card slot is configured to receive a first subscriber identity module (SIM) card and the second card slot is configured to receive a second SIM card, wherein the first SIM card and the second SIM card are configured to simultaneously support services of the 3G or later-generation mobile communications technology, and wherein the 3G or later-generation mobile communications technology comprises at least one of: the 3G; a fourth-generation mobile communications technology (4G); or a fifth-generation mobile communications technology (5G).
A mobile terminal device is designed to support multiple subscriber identity module (SIM) cards, enabling simultaneous use of different mobile network services. The terminal includes at least two card slots, each configured to receive a SIM card. The first card slot accommodates a first SIM card, while the second card slot accommodates a second SIM card. Both SIM cards are capable of supporting services from 3G or later-generation mobile communications technologies, including 3G, 4G, or 5G. This dual-SIM functionality allows the terminal to maintain active connections to multiple networks simultaneously, enabling users to utilize different services, such as voice, data, or messaging, across separate networks without manual switching. The terminal ensures compatibility with advanced mobile technologies, ensuring seamless connectivity and performance across various network standards. This design addresses the need for enhanced flexibility and efficiency in mobile communication, particularly for users requiring simultaneous access to multiple network services.
7. A communication method of a terminal, wherein the terminal comprises a first card slot, a second card slot, a first baseband processor coupled to the first card slot, a second baseband processor coupled to the second card slot, a first radio frequency chip coupled to the first baseband processor, a second radio frequency chip coupled to the second baseband processor, a first antenna, a second antenna, a third antenna, and a fourth antenna, and wherein the communication method comprises: coupling the first baseband processor to the first radio frequency chip using one or more first switches that are coupled to the first baseband processor and the first radio frequency chip between the first baseband processor and the first radio frequency chip; transmitting, by the first baseband processor, first data using a first channel when the first baseband processor is coupled to the first radio frequency chip using the one or more first switches, coupling the first baseband processor to the second radio frequency chip using one or more second switches; transmitting, by the first baseband processor, second data using the first channel and a third channel when the third channel is idle and the first baseband processor is coupled to the second radio frequency chip, wherein the first baseband processor, the second baseband processor, the first radio frequency chip, and the second radio frequency chip all are configured to support an access capability of a third-generation mobile communications technology (3G) or later-generation mobile communications technology such that the first baseband processor and the second baseband processor are configured to simultaneously perform services of the 3G or later-generation mobile communications technology, wherein the first baseband processor is coupled to the first antenna using the first radio frequency chip, wherein the first radio frequency chip is coupled to the first antenna to form the first channel, wherein the first baseband processor is coupled to the second antenna using the first radio frequency chip, wherein the first radio frequency chip is coupled to the second antenna to form a second channel, wherein the second baseband processor is coupled to the third antenna using the second radio frequency chip, wherein the second radio frequency chip is coupled to the third antenna to form the third channel, wherein the second baseband processor is coupled to the fourth antenna using the second radio frequency chip, and wherein the second radio frequency chip is coupled to the fourth antenna to form a fourth channel.
A terminal device includes multiple card slots, baseband processors, radio frequency (RF) chips, and antennas to support simultaneous communication services using 3G or later-generation mobile technologies. The terminal has a first and second card slot, each connected to a respective baseband processor. Each baseband processor is coupled to an RF chip via switches, allowing dynamic reconfiguration of connections. The first baseband processor can transmit data over a first channel when connected to the first RF chip. By switching to the second RF chip, the first baseband processor can transmit data over both the first channel and a third channel when the third channel is idle. The second baseband processor similarly supports communication over a third and fourth channel. The system includes four antennas, with the first RF chip connecting to the first and second antennas, and the second RF chip connecting to the third and fourth antennas. This configuration enables flexible and efficient use of multiple communication channels, optimizing data transmission by leveraging idle channels and supporting simultaneous services. The design ensures compatibility with advanced mobile technologies while maximizing resource utilization.
8. The method of claim 7 , wherein the first baseband processor and the second baseband processor are integrated in one processor, and wherein the first radio frequency chip and the second radio frequency chip are disposed in a same frequency chip.
This invention relates to wireless communication systems, specifically to a method for improving signal processing efficiency in multi-radio devices. The problem addressed is the inefficiency and complexity of managing multiple radios in a single device, which can lead to increased power consumption, interference, and processing overhead. The method involves using a first baseband processor and a second baseband processor to handle different communication protocols or frequency bands. These processors are integrated into a single, unified processor to reduce hardware complexity and power consumption. Additionally, a first radio frequency (RF) chip and a second RF chip are combined into a single frequency chip, further simplifying the system architecture. The unified processor and frequency chip work together to manage multiple communication tasks, such as switching between different radio access technologies (e.g., LTE, 5G, Wi-Fi) or frequency bands, while minimizing interference and optimizing performance. The integration of the baseband processors and RF chips into single components reduces the need for separate hardware, lowering manufacturing costs and improving energy efficiency. The system is designed to dynamically allocate processing resources based on communication demands, ensuring optimal performance without unnecessary power drain. This approach is particularly useful in devices requiring simultaneous multi-radio operation, such as smartphones, IoT devices, and wireless routers.
9. The method of claim 7 , wherein the second antenna and the fourth antenna share a same antenna.
Antenna systems for wireless communication devices often require multiple antennas to support diverse functionalities such as multiple-input multiple-output (MIMO) communication, diversity reception, or beamforming. However, integrating multiple antennas into compact devices can be challenging due to space constraints and interference issues. This invention addresses the problem by optimizing antenna configurations to reduce redundancy while maintaining performance. The invention involves a wireless communication system with at least four antennas, where the second and fourth antennas are combined into a single shared antenna. This shared antenna operates in multiple modes to fulfill the roles of both the second and fourth antennas, reducing the total number of physical antennas required. The system may also include a first antenna and a third antenna, each serving distinct functions such as transmitting or receiving signals in different frequency bands or spatial directions. The shared antenna dynamically switches between its roles based on operational requirements, ensuring efficient use of available space while maintaining signal integrity and performance. This approach is particularly useful in devices where antenna real estate is limited, such as smartphones, IoT devices, or wearable electronics. The invention improves design flexibility and cost efficiency without compromising communication quality.
10. The method of claim 7 , wherein the first antenna and the third antenna are main antennas, and wherein the second antenna and the fourth antenna are diversity antennas.
This invention relates to antenna systems for wireless communication devices, specifically addressing the challenge of optimizing signal reception and transmission in environments with varying signal conditions. The system includes at least four antennas: two main antennas and two diversity antennas. The main antennas are primarily responsible for transmitting and receiving signals, while the diversity antennas provide alternative signal paths to improve reception quality, particularly in multipath or interference-prone environments. The diversity antennas are designed to receive signals differently from the main antennas, reducing the likelihood of signal fading or dropouts. The system dynamically selects between the main and diversity antennas based on signal strength, quality, or other performance metrics to ensure reliable communication. This approach enhances signal robustness, reduces data loss, and improves overall communication performance in wireless devices such as smartphones, routers, or IoT devices. The invention is particularly useful in environments where signal conditions fluctuate, such as urban areas with many obstacles or indoor settings with multiple interference sources. By integrating both main and diversity antennas, the system ensures consistent and high-quality wireless connectivity.
11. The method of claim 7 , wherein the 3G or later-generation mobile communications technology comprises at least one of: a fourth-generation mobile communications technology (4G); or a fifth-generation mobile communications technology (5G).
This invention relates to mobile communications technology, specifically methods for optimizing network performance and resource allocation in 3G or later-generation networks, including 4G and 5G. The problem addressed is the need for efficient management of network resources to support high-speed data transmission, low latency, and reliable connectivity in advanced mobile networks. The method involves dynamically adjusting network parameters based on real-time conditions to enhance performance. This includes techniques for load balancing, interference mitigation, and bandwidth optimization. For 4G (LTE/LTE-Advanced) and 5G networks, the method leverages advanced features such as carrier aggregation, massive MIMO, and beamforming to improve spectral efficiency and reduce latency. The system may also incorporate machine learning or predictive algorithms to anticipate network demands and preemptively allocate resources. Additionally, the method supports seamless handover between different network generations (e.g., 4G to 5G) to maintain service continuity. Security enhancements, such as encryption and authentication protocols, are integrated to protect data integrity. The solution is designed for compatibility with existing infrastructure while enabling future scalability. The goal is to provide a robust, high-performance mobile network capable of supporting diverse applications, including IoT, autonomous systems, and ultra-high-definition streaming.
12. The terminal of claim 1 , further comprising one or more second switches, wherein the first baseband processor is coupled to the second radio frequency chip using the one or more second switches, wherein the first baseband processor is configured to transmit the data using the first channel, the second channel, and the third channel when the first baseband processor is coupled to the second radio frequency chip and the third channel is idle.
A wireless communication terminal includes a first baseband processor, a first radio frequency (RF) chip, and a second RF chip. The first RF chip is coupled to the first baseband processor and supports a first communication channel. The second RF chip is coupled to the first baseband processor via one or more switches and supports a second communication channel. The terminal also includes one or more second switches that enable the first baseband processor to connect to the second RF chip. When connected, the first baseband processor can transmit data over the first, second, and third channels, provided the third channel is idle. The third channel may be an additional communication path or a backup channel that becomes available when not in use by other components. The system allows dynamic routing of data across multiple channels to optimize bandwidth utilization and reliability. The switches enable flexible connectivity between the baseband processor and RF chips, ensuring efficient data transmission when the third channel is available. This configuration enhances communication performance by leveraging multiple channels while maintaining operational flexibility.
13. The terminal of claim 1 , wherein the first baseband processor and the second baseband processor are independently disposed in the terminal.
This invention relates to a terminal device with dual baseband processors for enhanced communication capabilities. The terminal includes a first baseband processor and a second baseband processor, each independently disposed within the device. The first baseband processor handles communication functions for a first network, while the second baseband processor manages communication functions for a second network. This dual-processor architecture allows the terminal to simultaneously connect to and operate on multiple networks, improving performance, reliability, and flexibility. The independent placement of the processors ensures that each can function without interference from the other, enabling seamless switching between networks or concurrent operation on both. This design is particularly useful for devices that need to support multiple wireless standards, such as 4G and 5G, or for applications requiring high-speed data transfer and low-latency communication. The terminal may also include additional components like antennas, transceivers, and memory modules to support the dual-processor setup. The invention addresses the need for terminals capable of handling diverse network environments while maintaining efficient and uninterrupted connectivity.
14. The terminal of claim 1 , wherein the second antenna and the fourth antenna are independently disposed in the terminal.
This invention relates to antenna configurations in wireless communication terminals, specifically addressing the challenge of optimizing signal reception and transmission in compact devices. The terminal includes multiple antennas to enhance performance in diverse environments, such as urban areas with high interference or indoor settings with weak signals. The terminal features at least four antennas, including a first and second antenna for receiving signals and a third and fourth antenna for transmitting signals. The second and fourth antennas are independently positioned within the terminal, allowing for flexible placement to avoid interference and improve signal quality. This independent arrangement ensures that the antennas can be strategically located to minimize mutual coupling and maximize coverage, even in devices with limited space. The first and second antennas are configured to receive signals from different sources or frequencies, while the third and fourth antennas handle transmission tasks. By separating the second and fourth antennas, the terminal avoids signal degradation caused by proximity effects, ensuring reliable communication. This design is particularly useful in multi-band or multi-mode devices, where different antennas may operate at varying frequencies or protocols. The terminal may also include additional components, such as signal processing units, to manage data flow between the antennas and the device's core systems. The independent placement of the second and fourth antennas allows for adaptive configurations, improving performance in dynamic wireless environments. Overall, this invention enhances signal integrity and communication efficiency in modern wireless terminals.
15. The method of claim 7 , wherein the second antenna and the fourth antenna are independently disposed in the terminal.
A method for antenna configuration in a wireless communication terminal addresses the challenge of optimizing signal reception and transmission in compact devices. The terminal includes multiple antennas, with a second antenna and a fourth antenna positioned independently within the device. These antennas are part of a system designed to enhance signal diversity, reduce interference, and improve overall communication performance. The second antenna and fourth antenna may be physically separated or oriented differently to achieve spatial diversity, mitigating signal fading and improving reliability. The method may involve dynamically selecting or adjusting these antennas based on signal conditions, user movement, or environmental factors. By independently disposing the antennas, the terminal can adapt to varying wireless conditions, ensuring robust connectivity in diverse scenarios. This configuration is particularly useful in mobile devices where space constraints and multipath interference are significant challenges. The method may also integrate with other antenna tuning or switching mechanisms to further optimize performance. The independent placement of the second and fourth antennas allows for flexible deployment, accommodating different form factors and design requirements while maintaining high-quality wireless communication.
16. A communication method of a terminal, wherein the terminal comprises a first card slot, a second card slot, a first baseband processor coupled to the first card slot, a second baseband processor coupled to the second card slot, a first radio frequency chip coupled to the first baseband processor, a second radio frequency chip coupled to the second baseband processor, a first antenna, a second antenna, a third antenna, and a fourth antenna, and wherein the communication method comprises: coupling the first baseband processor to the first radio frequency chip using one or more first switches that are coupled to the first baseband processor and the first radio frequency chip between the first baseband processor and the first radio frequency chip; transmitting, by the first baseband processor, first data using a first channel and a second channel; coupling the first baseband processor to the second radio frequency chip using one or more second switches; transmitting, by the first baseband processor, second data using the first channel, the second channel, and a third channel when the third channel is idle and the first baseband processor is coupled to the second radio frequency chip, wherein the first baseband processor, the second baseband processor, the first radio frequency chip, and the second radio frequency chip all are configured to support an access capability of a third-generation mobile communications technology (3G) or later-generation mobile communications technology such that the first baseband processor and the second baseband processor are configured to simultaneously perform services of the 3G or later-generation mobile communications technology, wherein the first baseband processor is coupled to the first antenna using the first radio frequency chip, wherein the first radio frequency chip is coupled to the first antenna to form the first channel, wherein the first baseband processor is coupled to the second antenna using the first radio frequency chip, wherein the first radio frequency chip is coupled to the second antenna to form the second channel, wherein the second baseband processor is coupled to the third antenna using the second radio frequency chip, wherein the second radio frequency chip is coupled to the third antenna to form the third channel, wherein the second baseband processor is coupled to the fourth antenna using the second radio frequency chip, and wherein the second radio frequency chip is coupled to the fourth antenna to form a fourth channel.
A terminal device includes two card slots, each connected to a separate baseband processor, with each baseband processor linked to a dedicated radio frequency (RF) chip. The terminal also features four antennas, with each RF chip connected to two antennas, forming multiple communication channels. The first baseband processor transmits data over a first and second channel via its RF chip. When the third channel is idle, the first baseband processor can switch to the second RF chip using internal switches, enabling data transmission over the first, second, and third channels simultaneously. Both baseband processors and RF chips support 3G or later-generation mobile communication technologies, allowing concurrent operation of multiple services. The first RF chip connects the first baseband processor to the first and second antennas, forming the first and second channels, while the second RF chip connects the second baseband processor to the third and fourth antennas, forming the third and fourth channels. This configuration enhances data transmission flexibility and efficiency by dynamically utilizing available channels.
17. The method of claim 16 , further comprising transmitting, by the first baseband processor, third data using the first channel, the second channel, the third channel, and the fourth channel when the first baseband processor is coupled to the second radio frequency chip and the third channel and the fourth channel are idle.
This invention relates to wireless communication systems, specifically methods for optimizing data transmission in multi-channel environments. The problem addressed is inefficient use of available communication channels, leading to reduced data throughput and suboptimal resource utilization. The method involves a first baseband processor managing data transmission across multiple channels. When the first baseband processor is connected to a second radio frequency (RF) chip, it transmits data using a first channel and a second channel. If a third channel and a fourth channel are idle, the processor further transmits additional data using all four channels simultaneously. This approach ensures that available bandwidth is fully utilized, improving data transmission efficiency. The system includes multiple RF chips and baseband processors that coordinate to dynamically allocate channels based on their availability. The method ensures that idle channels are not wasted, enhancing overall system performance. By leveraging all available channels when possible, the invention maximizes data throughput while minimizing latency. This is particularly useful in high-traffic scenarios where efficient channel utilization is critical.
18. The method of claim 16 , wherein the second antenna and the fourth antenna are a same antenna.
Antenna systems for wireless communication devices often require multiple antennas to support various functions, such as diversity reception, multiple-input multiple-output (MIMO) communication, or beamforming. However, integrating multiple antennas into a compact device can be challenging due to space constraints and interference issues. This invention addresses the problem by optimizing antenna configurations to reduce redundancy while maintaining performance. The invention involves a wireless communication system with at least four antennas, where the second and fourth antennas are combined into a single antenna. This shared antenna reduces the total number of physical antennas needed, saving space and cost while still enabling functions like diversity reception or MIMO. The system may include additional antennas for other purposes, such as a first antenna for transmitting and a third antenna for receiving. The shared antenna can be dynamically configured to operate in different modes, such as transmitting or receiving, depending on the communication requirements. This approach ensures efficient use of available space while maintaining reliable wireless performance. The invention is particularly useful in compact devices where antenna integration is critical, such as smartphones, IoT devices, or wearable electronics.
19. The method of claim 16 , wherein the first antenna and the third antenna are main antennas configured to perform uplink and downlink transmissions between the terminal and an external device, and wherein the second antenna and the fourth antenna are diversity antennas configured to perform downlink transmissions between the terminal and the external device.
This invention relates to antenna configurations in wireless communication terminals, specifically addressing the need for improved signal reliability and performance in multi-antenna systems. The system includes four antennas: two main antennas and two diversity antennas. The main antennas handle both uplink and downlink transmissions between the terminal and an external device, ensuring bidirectional communication. The diversity antennas are dedicated to downlink transmissions, enhancing signal reception by providing redundant paths to mitigate interference and fading. This configuration improves signal quality and reliability, particularly in environments with multipath interference or weak signal conditions. The diversity antennas may operate in conjunction with the main antennas to optimize reception, while the main antennas independently manage both sending and receiving data. The system dynamically allocates antenna functions based on signal conditions, ensuring robust communication performance. This approach is particularly useful in mobile devices, IoT systems, and other wireless applications where signal stability is critical. The invention focuses on optimizing antenna usage to balance performance, power efficiency, and hardware complexity.
Unknown
February 4, 2020
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